JP5043665B2 - Multi-lobe lock bolt - Google Patents

Description

[Related applications (priority claim)]
This application claims the benefit of US Provisional Application Nos. 60 / 605,704, filed Aug. 30, 2004, and U.S. Patent Application No. 11 / 146,678, filed June 7, 2005. .

  The present invention relates generally to rock bolts, and more particularly to a multilobe lock bolt configured to be installed relative to a collar swaged on the bolt.

  Some conventional lock bolts have a brittle pin tail, while other lock bolts do not. As shown in FIG. 1, a typical rock bolt 10 having a fragile pin tail 12 has a head 14, a threaded shaft 16, and a fragile pin tail 12 having an annular rib 18. Located at one end 20, the brittle pin tail 12 is located at the other end 22 of the bolt 10 and the threaded shaft portion 16 is located between the head 14 and the brittle pin tail 12. As shown in FIG. 1, initially the fragile pintail 12 and threaded shaft 16 are inserted through openings 24, 26 provided in two or more workpieces 28, 30, and the collar 32 is slid over the bolt 10. , Positioned near the threaded shaft 16. The installation tool 40 is then engaged with the collar 32 and the fragile pintail 12 as shown in FIG. Specifically, as shown in FIG. 3, jaw 41 of installation tool 40 grips pintail 12 and pulls (as represented by arrow 42). At this time, the anvil 43 of the installation tool 40 pushes down the collar 32 (as represented by the arrow 44) so that the collar 32 is swaged onto the bolt 10. By this swaging process, the collar 32 is deformed and generally holds the threaded shaft 16 of the bolt 10. When the collar 32 is swaged, the pintail 12 is continuously pulled until it is broken as shown in FIG. 4, and is installed on the workpieces 28, 30 and secured by the collar 32. Leave. Similarly, if the locking bolt is given as a type without a brittle pin tail, the threaded portion of the bolt is gripped and pulled when the collar is swaged. When the collar is fully swaged, the bolt is released, leaving the threaded portion intact.

  Such lock bolts and tools for installing such lock bolts are generally known in the art. For example, a typical tool for installing a rock bolt with a brittle pin tail is disclosed in US Pat. No. 2,114,493. The tool has an anvil for swaging the collar and a jaw for gripping and pulling the pintail.

  Some prior art lock bolt screws, such as those shown in FIGS. 1-4, are helical. Regardless of whether the lock bolt has a brittle pin tail, the helical screw rotates the collar away from the lock bolt when the lock bolt is installed (i.e., the collar is swaged onto the bolt), Then, it can be re-threaded onto the lock bolt (or a new nut can be screwed onto the lock bolt). A problem associated with providing a lock bolt with a standard helical thread is that when the collar is swaged onto the lock bolt, it will vibrate and become loose.

  U.S. Pat. No. 2,531,048 discloses a lock bolt that attempts to solve this problem. The lock bolt has an annular rib instead of a standard helical screw. By being annular rather than spiral, when the collar is swaged on the rib, the collar is less likely to loosen due to vibration. However, this lock bolt presents new drawbacks. That is, when the collar is swaged onto the ribs, the collars must be broken and removed from the ribs, not rotated and removed from the lock bolts. As such, the collar cannot be removed from the rib and rotated back onto it. In fact, because the ribs are annular, even a new collar cannot be screwed onto the lock bolt. Instead, the swaging process must be repeated to re-fasten the lock bolt.

[Purpose and summary]
One object of an embodiment of the present invention is to provide a lock bolt that prevents the collar from vibrating and loosening after installation, and further allows the collar to be selectively rotatably removed and re-installed on the lock bolt. It is to provide.

Briefly, and in accordance with at least one of the foregoing objects, embodiments of the present invention provide a lock bolt. The lock bolt includes a head portion and a shaft extending from the head portion. The shaft has at least a threaded portion with a multilobe profile . The collar can be swaged onto the multi-lobe threaded portion, and the lobe or high point prevents the collar from subsequently vibrating and loosening from the thread. The fact that the section with the multi-lobe profile is also threaded allows the collar to be selectively rotatably removed and re-installed on the locking bolt (or the swaged collar is removed) And allow a normal threaded nut to be installed on the lock bolt). Prior to swaging, the collar may initially have a multi-sided hole that preferably corresponds generally to the contour of the cylindrical hole or the multi-lobe type portion of the rock bolt. The lock bolt may have a brittle pin tail. In this case, the multi-lobe threaded portion is disposed between the head portion of the bolt and the brittle pin tail. The brittle pin tail can be provided with an annular rib. Alternatively, the brittle pin tail can be provided with the same thread as the multi-lobe threaded portion of the lock bolt.

  The organization and approach of construction and operation of the present invention, together with further objects and advantages thereof, are best understood by referring to the following description taken in conjunction with the accompanying drawings. In the drawings, like reference numbers identify like elements.

[Explanation]
While the invention is amenable to different forms of embodiment, that embodiment is shown in the drawings and will now be described in detail. It should be understood that this description is to be considered as illustrative of the principles of the invention and is not intended to limit the invention to what is shown and described herein.

  5-7 depict a lock bolt 100 according to an embodiment of the present invention. The lock bolt 100 is similar to the prior art lock bolt 10 shown in FIGS. 1-4, which includes a head 102, a threaded shaft 104, and a brittle pin tail 106 having an annular rib 108. The head 102 is located at one end 110 of the bolt 100, the brittle pin tail 106 is located at the other end 112 of the bolt 100, and the threaded shaft portion 104 is between the head 102 and the brittle pin tail 106. To position. The difference between the lock bolt 100 shown in FIGS. 5-7 and the prior art lock bolt 10 shown in FIGS. 1-4 is that the threaded shaft 104 of the lock bolt 100 shown in FIGS. Rather than being screwed in a spiral, the fact is that it has a multilobe or multi-sided threaded part. This means that the screw has a high point 114 and a low point 116 as shown in FIGS.

  For example, the thread is provided with five lobes or high points (eg, as shown in FIGS. 8-10). This is an HP-5 screw as disclosed, for example, in US Pat. Nos. 3,875,780 and 3,935,785, both of which are fully incorporated herein by reference. Instead, the threaded portion is provided with more or less than five lobes. For example, the threaded portion may be a quadrobe type (ie, with four high points), a trilobe type (ie, with three high points), an elliptical type (ie, with two high points), etc. Given in form.

  Nevertheless, the fact that the threaded portion 104 of the lock bolt 100 is multi-lobe and has high and low points, the fact that the collar 120 vibrates when swaged on the lock bolt 10. Avoid dropping off. This is because vibration alone is not sufficient to move the low point 122 (see FIG. 10) of the swaged collar 120 beyond the high point 114 of the multi-lobe portion 104 of the lock bolt 100. . At the same time, the fact that the threaded portion 104 is actually threaded and multi-lobe is that the collar 120 is intentionally rotated, if necessary, using a tool that provides sufficient torque to the collar 120. Can be removed from the lock bolt 100.

  5-7 depict the installation of the lock bolt 100. This installation process is exactly the same as the installation process used to install the lock bolt 10 shown in FIGS. To install the lock bolt 100 shown in FIGS. 5-7, the Textron Fastening System hydraulic-electronic power tool T30 type 7341-022000 and the Textron Fastening System HydraPac liquid The pressure type power unit HP21 type 73401-02000, HP41 type 73400-02000 or HP51 type 73404-02000 can be used. Alternatively, some other suitable installation tool can be used.

Initially, the fragile pintail 106 and threaded shaft 104 are inserted through openings 24, 26 provided in two or more workpieces 28, 30, and the collar 120 is adjacent to the threaded shaft 104 on the bolt 100. Arranged. As shown in FIG. 8, the collar 120 can be initially provided with a multi-lobe or multi-sided through-hole 130. Collar 120 is preferably provided so as to have a through hole 130 having a contour corresponding to the contour of the multi-lobed portion 104 of the locking bolt 100. In other words, if the multi-lobe shaped portion 104 of the lock bolt 100 has five lobes or high points (like HP-5 screws), the collar 120 will also have a through-hole 130 with five high points 131 as well. It is preferable to be provided. The fact that collar 120 is provided having a through hole 130 having a contour corresponding to the contour of the multi-lobed portion 104 of the lock bolt 100, provide a uniform deformation of the collar 120 during swaging.

In addition, collar 120 is the fact that is provided so as to have a through hole 130 having a contour corresponding to the contour of the multi-lobed portion 104 of the lock bolt 100, collar 120 to be able to help for Installation. Specifically, the collar is placed on the bolt and rotated slightly. In this case, an interference fit exists between portion 104 and collar through-hole 130. The installation tool is then engaged with the pintail 106 and the collar 120, and the swaging operation is performed. Instead, as shown in FIG. 9, the collar 120 is initially provided with a cylindrical or other shaped through hole 130.

  Nevertheless, the installation tool 140 is engaged with the collar 120 and the fragile pintail 106 as shown in FIG. Specifically, as shown in FIG. 6, the jaw 142 of the installation tool 140 grips and pulls the pin tail 106. At this time, the anvil 144 of the installation tool 140 pushes down the collar 120 so that the collar 120 is swaged onto the bolt 100. By this swaging, the collar 120 is deformed and generally assembled to the multi-lobe threaded portion 104 of the bolt 100 (FIG. 10 shows the collar 120 swaged on the multi-lobe-shaped portion 104 of the lock bolt 100). (Similar to the sectional view).

  The installation tool 140 preferably swages only a portion 150 of the collar 120 onto the threaded portion 104 (see FIG. 6). In this case, the remaining portion 152 remains unswaged. This is to facilitate assembly and manufacture of the assembly. The non-swaged portion 152 of the collar 120 preferably has a hexagonal contour surface 154. In this case, the collar 120 can be removed later using a standard hexagonal tool. When the collar 120 is swaged, the pintail 106 is continuously pulled until it breaks, as shown in FIG. 7, and is installed in the workpieces 28, 30 and secured by the collar 120. Leave. Similarly, if the locking bolt is given as a type without a brittle pin tail, the threaded portion of the bolt is gripped and pulled when the collar is swaged. The bolt is then released when the collar is fully swaged.

When the collar 120 is swaged onto the lock bolt and the lock bolt 100 is fully installed and secured by the collar 120, the collar 120 will vibrate and fall out due to the multi-lobe profile of the threaded portion 104. There will be no. Specifically, vibration alone does not allow the low point 122 of the collar 120 to get over the high point 114 of the multi-lobe portion 104 of the lock bolt 100, as shown in FIG. In other words, the multi-lobe profile of the portion 104 provides a predetermined amount of powerful torque that attempts to resist rotation in response to vibration. At the same time, the collar 120 can be simply removed intentionally by using a tool that provides sufficient torque (eg, by using a six-sided tool that provides torque against the surface 154). In this case, the low point 122 of the collar 120 rides over the high point 114 of the multilobe portion 104 of the rock bolt 100.

  Once the collar 120 is swaged onto the lock bolt 100, intentional removal of the collar 120 (ie, rotation of the collar 120 using a tool) causes a screw to be formed in the collar's through-hole 130. . The thread formed in the collar 120 allows the collar 120 to be easily rotated back onto it after the collar 120 is intentionally removed from the threaded portion 104 of the lock bolt 100. After the collar 120 is rotated back onto the lock bolt 100, the following points are expected. That is, the fact that the threaded portion 104 of the lock bolt is multi-lobe is the same as when the threaded portion 104 of the lock bolt 100 is provided to be helically screwed by a standard spiral screw, i.e. conventional. As provided by the technology (that is, the lock bolt 10 shown in FIGS. 1 to 4), the collar 120 does not vibrate and fall off. In other words, there is a certain amount of powerful torque that exists beyond what is provided when the portion 104 has a standard helical thread.

  Although it has been described above that the collar 120 is preferably provided with a hexagonal surface 154 from the beginning to facilitate removal of the collar 120 with a hexagonal tool, the collar 120 may also be provided without such a surface. be able to. Such a surface can be formed in the collar 120 by the anvil 144 of the installation tool 140 during the swaging operation.

FIG. 11 depicts a rock bolt 200 according to an alternative embodiment of the present invention. The lock bolt 200 is very similar to the lock bolt 100 shown in FIGS. The only difference is that the brittle pin tail 202 does not have an annular rib and provides a multi-lobe threaded profile similar to the multi-lobe portion 104 of the lock bolt 200 (or lock bolt 100). In this way, both the lock bolt portion 104 that ultimately receives the collar and the pin tail portion 202 may be threaded simultaneously using the same threading process. Alternatively, the pintail can be provided with a spiral non-lobe screw.

  While embodiments of the invention have been illustrated and described, it will be appreciated by those skilled in the art that various modifications of the invention can be devised without departing from the spirit and scope of the disclosure.

Figure 2 depicts a prior art lock bolt having a head, a helical threaded shaft portion, and a brittle pin tail, showing a pre-swaged collar positioned near the helical threaded shaft portion. FIG. 2 depicts the installation of the lock bolt shown in FIG. FIG. 2 depicts the installation of the lock bolt shown in FIG. FIG. 2 depicts the installation of the lock bolt shown in FIG. Figure 8 depicts the installation of a lock bolt according to an embodiment of the present invention. Figure 8 depicts the installation of a lock bolt according to an embodiment of the present invention. Figure 8 depicts the installation of a lock bolt according to an embodiment of the present invention. A view (similar to a cross-sectional view) of the lock bolt and collar before swaging is given. In this case, the collar is given as having multifaceted holes. FIG. 9 is similar to FIG. 8 but shows the situation where the collar is given as having a cylindrical hole. A view (similar to a sectional view) of the lock bolt and collar after swaging is given. It is a perspective view of the lock bolt concerning an alternative embodiment of the present invention.

Claims (8)

A lock bolt system comprising a lock bolt and a collar,
The lock bolt has a head portion, a frangible pintail and a shaft disposed between said head portion and the frangible pintail, said shaft threaded portion having a multi-lobed cross-sectional shape with a screw Have
The collar has a through hole having a multi-lobed cross-sectional shape corresponding to the multilobed cross-sectional shape of the threaded portion of the shaft of the locking bolt, wherein the collar includes a swaging moiety, non swaged moiety DOO further comprising, said swaging moiety, together with a cylindrical outer surface, Ri swaged can der onto the threaded portion of the shaft of the locking bolt, the non-swaged moiety is hexagonal contour Has an outer surface,
The threaded portion of the shaft of the lock bolt is threaded and multilobe so that the threaded portion of the shaft is torqued by a standard hexagonal tool against the hexagonal contour outer surface of the non-swageable portion of the collar. by providing a lock bolt system said collar selectively rotatably removed, and characterized that you have been configured to be re-installed on the locking bolt. Threaded-out parts of the said shaft, a point several low and, according to claim 1 and a plurality of high points than said low point spaced in a direction perpendicular to the central axis from the central axis of the shaft Rock bolt system. -Out threaded parts of the said shaft, a point several low and, according to claim 1 wherein the even lower point and a five high point away in a direction orthogonal to the central axis from the central axis of the shaft Rock bolt system. The lock bolt system of claim 1 , wherein the threaded portion of the shaft is configured such that a threaded nut can be installed on the lock bolt when the swaged collar is removed from the shaft. The collar locking bolt system according to claim 1 having a hole of polygonal corresponding to the portion of the shaft. The rock bolt system of claim 1, wherein the fragile pintail has a multi-lobe cross-sectional shape. The rock bolt system according to claim 6, wherein the fragile pin tail has a plurality of low points and a plurality of high points separated from the central axis of the shaft in a direction perpendicular to the central axis. The lock bolt system according to claim 1, wherein the fragile pin tail and the threaded portion of the shaft have the same threaded portion.

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